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SYMPOSIUM
PART 3
The Role of Care in Bringing Human and Social Capital to Life in Nursing
William P. Fisher, Jr, PhD with over 25 years professional experience, Dr. William P. Fisher, Jr. has developed a complementary array of skills focused on improved information quality and systems in health care and education. He is internationally recognized for contributions to both ends of the theoretical-philosophical to practical-analytic spectrum. Dr. Fisher's recent work explores possibilities for and projects likely consequences of equating tests and surveys measuring the same constructs, so that all instruments in an area measure in the same unit of comparison and with known uncertainty characteristics.
Jane F. Sumner, Ph.D, RN, APRN, BC has been investigating caring in nursing for many years because of her varied experiences in practice over 48 years. Her original nursing education was in New Zealand and her 3 university degrees are from the US. For the last 19 years she has been a nurse educator.
1
Theory, Care, and Nursing:
The Capital Value of a Practical Synthesis
William P. Fisher, Jr., Ph.D.
Jane F. Sumner, Ph.D, RN, APRN, BC
University of California, Berkeley and Lousiana State University, New Orleans
[email protected], [email protected]
Abstract
In the history of science, predictive theories enabling accurate and confident innovations
typically emerge only after phenomena can be represented and reproduced consistently in
standardized forms. These technological forms are structural transformations of the original
forms of life from which meaning was poetically and metaphorically abstracted. A new basis for
theoretical and practical developments in caring in nursing follows from close consideration of
the experience of physis, spontaneously self-organizing natural processes. The physis of a wide
array of nursing constructs exhibits consistencies likely to lend themselves to standardized
technological representations. If they do, new horizons should emerge for theory development
and innovation around nursing’s human and social capital. Probabilistic Rasch models making
use of sufficient statistics and requiring separable parameters will be of significant value. How to
retain a close connection with the original meaning-giving sources in physis will be a matter of
ongoing concern.
2
Framing the Problem
Background. “There is nothing so practical as a good theory” (Lewin, 1951, p. 169). Good
theory provides explanatory power, predictive control, efficiency, and confidence that a
phenomenon is as thoroughly understood as it needs to be for practical purposes. In the history of
science, good theories almost always emerge from social networks sharing standardized
technology and instrumentation (Bijker, Hughes, and Pinch, 2012; Bud and Cozzens, 1992;
Daston and Galison, 2007; Hankins and Silverman, 1999; Ihde, 1991, 1998; Latour, 1987, 2005;
Wise, 1995). Historically, scientific productivity is maximized when phenomena can be
consistently reproduced for controlled study, and information is shared within a community of
practice in standardized terms, images, and metrics. It seems that individual and group learning
and innovation often depend extensively on opportunities to engage with others in the repetitive
play of structured games (Barab, Scott, Siyahhan, Goldstone, Ingram-Goble, et al., 2009; Crease,
1993; Wise, 1995). This behavioral and cognitive orientation persists even when the rules of the
games played are not well defined, and winning becomes less associated with the desired
outcomes of scientific or economic advancement than with secondary outcomes presenting mere
appearances of new learning and productivity (Bakker, van Dijk, Wicherts, 2012; Gertler, 2010).
The creative power of social networks in technological, business, political, and artistic
innovation is very much of contemporary cultural interest globally. The exercise of that power,
however, is nothing new, as it has driven industrial, scientific, and democratic revolutions for
centuries. Innovation has always been a team sport in some respects, but its team characteristics
have become of increasing relevance as the technology for networked communications has
proliferated (Degen, 2009). One of the most important lessons of technology’s ubiquitous
presence is that generalizable creativity depends on systemically shared and complementary
3
moral, economic, and scientific values (Schaffer, 1992; Zak, 2008), taking these as both guides
to right thinking and acting, as well as standardized numeric metrics and common currencies.
A fundamental barrier to the conceptualization and formation of shared values is the
assumption that qualitative and quantitative data and methods entail paradigmatically distinct
philosophical commitments (Bryman, 2007; Moffatt, White, Mackintosh, and Howel, 2007). On
the contrary, "a good implicit phenomenology is often concealed in the most objectivistic
sciences” (Ricoeur, 1967a, p. 219). The apparent ontological divide between qualitative and
quantitative methods may then be only an artifact of unnecessary assumptions, and not an
inherent structural feature of the scientific landscape (Fisher, 2003a, 2003b, 2004, 2010; Fisher
and Stenner, 2011). Nursing, of course, attends to human care needs, and accordingly has to
account for a complex array of physical, chemical, biological, psychological, and social factors
not easily reduced to a simple, standardized model. Theory development has been
characteristically more qualitative, hermeneutic and phenomenological (Benner, 1994, 2001;
Dunlop, 1986; Sumner, 2001, 2006; Watson, 1999) and has understandably, then, not proceeded
in nursing as it did in physics.
It may, however, be worthwhile to consider the problems of simplification and theory
development from a fresh point of view. Recent studies of model-based reasoning processes in
the history of science (Nersessian, 2002, 2008) illustrate the productive use of analogies by
James Clerk Maxwell, for instance, in the development of electromagnetic theory. Metaphor has
been found ubiquitous in discourse, including in science and engineering, with the effect of
rendering discovering and invention poetic (Black, 1962; Brown, 2003; Lakoff and Johnson,
1980). This kind of research suggests that nursing may harbor phenomena not previously
examined in terms of their viability as objects of study amenable to analogical models and
4
processes for validating them. In fact, because its primary raison d’etre centers on care and
caring, which are characteristic of a quintessentially human mode of being, nursing may have an
opportunity to make a particularly unique and powerful contribution to the development of a new
kind of art and science.
But what are the unexamined phenomena nursing could more productively focus on? What
kind of theoretical developments are possible that are not yet on the record or being pursued?
How are the relevant phenomena to be identified? It may help to look to the history of science
for a starting point. A source for an analogical perspective is provided by de Solla Price (1986, p.
240), who observed,
Historically, we have almost no examples of an increase in understanding being applied to
make new advances in technical competence, but we have many cases of advances in
technology being puzzled out by theoreticians and resulting in the advancement of
knowledge. It is not just a clever historical aphorism, but a general truth, that
'thermodynamics owes much more to the steam engine than ever the steam engine owed to
thermodynamics.'
An instance of supporting evidence is provided by Kuhn (1977, p. 90), who noted that seven of
the nine theoreticians who succeeded at least partially in quantifying energy conversion
processes were engineers or were working directly on engines when they made their
contributions to the physics of energy conservation.
In nursing, care is a primary focus of both practice and theory. Nursing theoreticians tend
to be practicing nurses with firsthand experience in observing the association of care with
healing. Other nursing theoreticians may be practicing teachers who routinely observe the effect
of their care and attention on the progression of learning in students. There is, however, of course
5
nothing like a care engine that mechanically functions in a physically predictable way, and that
could be experimentally studied and manipulated in accord with engineering principles. But this
literal analogy could be subtly configured in terms of a more ontologically appropriate metaphor
drawn from the ancient Greek concept of physis.
In nursing, physis is understood in terms of the natural and spontaneous healing and
growth experienced as a result of good nutrition, sleep, and hygiene (Wynn, 2006). The term is
also taken to refer to the satisfaction a nurse can experience in the knowledge of having provided
effective quality care (Sumner, 2010). As a philosophical concept, however, physis concerns
natural processes of coming into and going out of existence. Physis is the unsought, poetically
emergent creation and destruction of beings, something that comes from within these beings
themselves, in the manner of a flower, blooming. Physis stands in clear contrast with the ready
availability of technological devices and methods for the automatic, effortless production and
consumption of commercial goods (Heidegger, 1977, p. 10; Glazebrook, 2000, pp. 164-165).
There is a tendency in the modern world to assume that technology defines existence, and
that all important problems have been or will be solved by means of technology. Art, poetry,
music, handicrafts, and natural wilderness are often experienced as reminders of a lost
connection with the earth or a spiritual realm, and they also often convey the feeling that there is
little or nothing that can be done to restore what has been lost.
But awareness of physis and the methodical application of technique both nonetheless
follow from a concern with care. To the extent that one engages in dialogue and negotiation
instead of violence and domination, consideration for another’s human vulnerability has been
shown, a choice in favor of caring has been made, and at least some trace of an experience of
physis is obtained (Gadamer, 1991, p. 61; Habermas, 1995; Heidegger, 1962; Irigaray, 1984;
6
Ricoeur, 1967b). Even in the context of contemporary nursing practice, which can at times seem
awash with technological fixes and immutable control mechanisms, high quality care is still a
goal and is often achieved (Locsin, 2005; Sumner, 2008).
Despite the persistent evidence of physis in nursing, the fundamental value of nursing care in
creating and increasing human and social capital is elusive and remains largely unaddressed
(Royal, 2012). Though an artful apprehension of the value of physis in nursing care (Wynn,
2006) is of great value for symbolizing the safeguarding of care, there is a longstanding and
increasingly urgent need for a poetic crafting of a new root metaphor that resonates with and
captivates the imaginations of everyone providing and affected by that care. Most pointedly,
instead of remaining uncritically rooted in assumptions of what it means to assign value
methodically in nursing practice, in nursing education, or in a nursing research study, those
methods must themselves be broken down to their own authentic expressions of physis and then
reconstructed to meet the needs for new representations (Sumner, 2001, 2006, 2008; Sumner and
Fisher, 2008). Put more directly, cynical games played with meaningless, locally varying ordinal
scores and underpowered p-values as means to the ends of publication and promotion (Bakker, et
al., 2012) must be replaced with authentic play involving meaningful, globally invariant interval
measures and substantively significant, reproducible outcomes.
A hermeneutic and phenomenological approach to this deconstruction and reconstruction of
method begins from attentive care for the object of the conversation as the essential factor in
creating an authentic science. Work of this kind pursued in relation to the natural sciences
(Crease, 1993; Heelan, 1983, 1998; Ihde, 1998, 2012; Glazebrook, 2000) has been extended and
brought to bear in the social sciences (Fisher, 2003a, 2003b, 2004, 2010; Fisher & Stenner,
2011). Method in this sense playfully appropriates the experience of physis (Gadamer, 1989;
7
Ricoeur, 1981, pp. 182-193). The unexamined phenomena nursing needs to advance the theory
and practice of care reside in the physis that can be found and created in the repeated self-
organization of regular patterns in data recorded as responses to questions on patient surveys,
student tests, and clinical assessments. These questions can be intentionally designed, so far as
possible, to reveal or construct reproducible patterns interpretable as evidence that the construct
measured exists as an identifiable entity in the world. Once established as persisting as
repeatedly identifiable objects of conversations, these patterns could form the basis for a new
technological embodiment of the physis of caring, which in turn could provide a context in which
the nursing profession could collectively puzzle out improved theories of caring.
Method here recovers its root sense of following along after (meta-) the object of inquiry on
the path (odos) it takes up of its own accord. Hence, Gadamer (1989, p. 460) points out that in
method, properly understood, "what thought experiences is the movement of the thing itself." He
continues, observing that
The Greeks...did not conceive understanding as a methodic activity of the subject, but as
something that the thing itself does and which thought 'suffers.' This activity of the thing
itself is the real speculative movement that takes hold of the speaker. We have sought the
subjective reflection of it in speech. We can now see that this activity of the thing itself, the
coming into language of meaning, points to a universal ontological structure, namely to the
basic nature of everything toward which understanding can be directed. Being that can be
understood is language. The hermeneutical phenomenon here projects its own universality
back onto the ontological constitution of what is understood, determining it in a universal
sense as language and determining its own relation to beings as interpretation. (pp. 474-475)
8
Physis can be methodically apprehended, appropriated, and embodied in a technique, however,
only to the extent that "The first concern of all dialogical and dialectical inquiry is a care for the
unity and sameness of the thing under discussion" (Gadamer, 1991, p. 61; original emphasis).
Thus, the focus of physis-oriented research on patient care needs, on student care instruction, and
on nursing care competency begins from the identification of constant patterns stable enough to
be repeatedly recreated across different local conversations involving different people at
different times and places asking different questions that nonetheless still all pertain to a single
construct.
Establishing the existence of these patterns of invariant regularity is, however, only the
beginning of this kind of research. A new paradigm for nursing research and practice based in
careful attention to the physis of care cannot simply rework existing concepts of validity and
reliability; it must begin with a fresh orientation to goals not previously pursued in systematic
ways. The overarching methodological framework must be phenomenological, but in the
existential sense of focusing on the cycle of reduction, application, creative destruction, and
return to reduction described by Heidegger (1982, pp. 19-23, 320-330; Marion, 1998; also see
Fisher, 2010; Fisher and Stenner, 2011).
Though they are necessary to the advancement of knowledge, the identification and local
study of these patterns of invariance are not sufficient in themselves to the task. Stopping with
this reductive moment in the movement through the method is a failure to follow through with
enough care for the physis experienced to extend it to others for application. As Ricoeur (1967b)
puts it, to cut off the conversation in this way commits the violence of the premature conclusion.
Most research employing factor analysis or statistical analysis of ordinal scores makes untenable
assumptions about the meaning of the numbers studied, and more importantly fixes the meaning
9
of the results in relation to the particular questions asked and the particular persons answering
them. This inability to leave the question open, in the sense of supporting transparent
comparability with other studies of the same construct, is the fundamental shortcoming of what
passes for quantitative methods in most mainstream research in nursing employing test, survey,
and assessment data. Science is supposed to be an accumulation of aggregate knowledge, but
even when results are comparable across samples and instruments, researchers usually fail to
make those comparisons (Fisher, 1997, 1999).
To arrive at a place from which the collective intelligence of the field of nursing can be
focused and harnessed—to meet the challenges of advancing theory and practice—standards are
essential. Everyone involved must be able to know when they are experiencing the phenomenon
they intend to experience, and they must be able to see how much of it there is. Standardized
terms, images, and metrics must be devised for the things themselves to be brought into language
as shared objects in the real world. The universality of scientific phenomena is not spontaneously
and effortlessly created from the experience of physis. Things do not automatically pop into
language in some self-initiated and instantaneous way. As Gadamer says, being that can be
understood is language, but that does not mean things come into language all by themselves.
Rather, quite significant resources must be invested in standardization to give a tangible, material
form to the otherwise unenculturated phenomena apprehended when an invariant pattern first
presents itself (Hunter, 1980; Latour, 1987, p. 251).
Standardization makes it possible for observers of the phenomenon to use the same
language in referring to it, reducing the opportunities for confusion that arise when different
words, images, and numbers are used to refer to the same thing. Persistent quantitative patterns
can be fixed in standard metrics to which all instruments measuring the construct are linked. In
10
the history of science, metrological networks have been a means by which communities of
research and practice have united themselves in common purpose and have achieved
extraordinary results (Latour, 1987, pp. 247-257, 2005; Hunt, 1994; Kuukkanen, 2011; Wise,
1995). In the context of the phenomenological method’s careful sensitivity to appropriating the
experience of physis, it is essential to set up metrological systems that distribute the media of a
shared frame of reference to everyone interested in participating in it. Existing examples of such
media for shared frames of reference include clocks, rulers, thermometers, weight scales,
speedometers, etc.
This may sound like a high standard to achieve, and it is. Achieving it would be an
unprecedented accomplishment in the human and social sciences. It is true that data exhibiting
invariant patterns of the kind described here are commonly produced in high stakes tests and
research in education, psychology, and health care employing a variety of probabilistic models
(Rasch, 1960, 1977; Andrich, 1978, 2004; Bezruzcko, 2005; Bond and Fox, 2007; Fisher and
Wright, 1994; Wilson, 2005; Wright, 1977, 1999). Nursing has a fairly extensive history of
research and licensure applications employing models requiring data exhibiting the
characteristics of physis (Fox, 1999; Hagquist, Bruce, & Gustavsson, 2009; Holm & Kavanagh,
1985; Lee and Fisher, 2002; O’Neill, Marks, and Reynolds, 2005; Smith, Conrad, Chang, &
Piazza, 2002; Sumner & Fisher, 2008), though the possibilities for capitalizing on physis in this
context has not been generally appreciated for its particular value (Strickland, 2002).
The local definitions of invariant constructs described in some instances of measurement
research and practice do not make their full value evident because nothing is done to link results
together in a shared framework of common standards. Even when multiple separate calibrations
of different instruments measuring the same thing, or of the same instrument calibrated on
11
different samples, are available in the published literature of a field, comparing or equating the
available metrics is rare (Fisher, 1997, 1999). It seems as though the idea of science as an
accumulated compendium of learning has been lost.
The full value of local instrument calibrations can be realized only if and when the invariant
patterns identified are represented systematically in an interconnected network of point-of-use
applications unified by standards (Fisher, 2012; Fisher, Harvey and Kilgore, 1995: Fisher,
Harvey, Taylor, Kilgore, and Kelly, 1995; Stenner and Smith, 1982; Stenner and Stone, 2010).
Of course, to arrive at a new system of that sort, existing systems of research and practice that
are not organized around coordinated expressions of physis must be replaced using the processes
of creative destruction deployed in the third moment of the phenomenological method. Those
conversations will not be likely to occur until dissatisfaction with the anomalies and
inconsistencies of the existing paradigm coalesce into a broad movement in which firm
conceptions of the first two moments are in place.
Ontological Midwifery of Care
Situating caring in a “transpersonal framework of conscious intentionality,” Watson (1999,
pp. 237, 243-259) notes that postmodern analyses and concepts often fail to move beyond critical
evaluations of failed philosophies or methods to new ways of constructing possibilities for
healing environments. If, following Watson, nurses are to be able to assume roles as “ontological
architects” designing and inhabiting healing spaces, they will need (a) a more tightly interwoven
and systematic integration of ontology and method, and (b) a new science of ontological research
and development to support them.
Ontology, as the logic of existence and of how things come into being, becomes
methodological when the physis of a form of life is captured or recorded, and is made routinely
12
repeatable. The ontology of care is, however, specifically focused on living being, as opposed to
mechanical building materials. Architectural space is an apt metaphor for the configuration of
attitudes, skills, and relationships needed to create a healing environment. The metaphor falls
short, however, in its implications as they are pursued into the details of nursing practice.
Consistent methodological principles follow more directly from the metaphor of the Socratic
midwife than they do from the mixed metaphor of “ontological architects.”
Socrates’ dialectical method was intended to ensure that his students’ and colleagues’
conceptual offspring would be born with the metaphoric equivalents of good eyes, straight noses,
and ten fingers and toes (Plato, 1961, pp. 853-856, or 149 ff. in standard Stephanus pagination).
So, too, must nursing attend to the midwifery of both caring practitioners able to take on lives of
their own as professionals, and of caring processes and outcomes able to bring patients back to
their productive, interdependent lives.
How can ontological midwifery be systematically focused on caring in nursing? There
would seem to be an almost unspannable breach between the ontological assumptions of
contemporary measurement practice in nursing and the qualitative depiction of the practical
demands experienced in managing care, as is described in other contexts by Bryman (2007) and
Moffatt, et al. (2007). Recent texts (such as Watson, 2009) on measuring caring in nursing show
that nursing has not yet recognized or adopted to a significant degree relevant advances in
measurement theory and practice made over the last several decades, though there are some
exceptions (Fox, 1999; Hagquist, Bruce, & Gustavsson, 2009; Holm and Kavanagh, 1985; Lee
and Fisher, 2002; O’Neill, Marks, and Reynolds, 2005; Smith, Conrad, Chang, & Piazza, 2002;
Sumner & Fisher, 2008). A significant and unaddressed challenge then concerns how to better
13
inform nursing’s ontological aspirations with improved methods that remain authentically
connected with its caring mission.
Husserlian phenomenology became the method of ontology and of scientific philosophy in
Heidegger’s (1982) critical synthesis, though Husserl himself contributed more to that synthesis
than has generally been recognized (Marion, 1998, pp. 43-51, 143-146). Heidegger, like many
who came later in 20th
century Continental philosophy, focused extensively on the third,
creatively destructive or deconstructive moment in the ontological method, to the near exclusion
of the other two moments, reduction and construction. As Heidegger (1982, pp. 19-23, 320-330)
and Derrida (2003, p. 62) recognized, however, engagement with the processes of reduction and
construction is unavoidable in that writing itself reduces infinite potentials to a limited text, and
inherently involves the positive intention to express some kind of meaning (Caputo, 1997, p. 80;
Fisher, 2010; Ruin, 2011, p. 80).
The iterative cycling through the process of reduction, application, and creative destruction
is not so much a technique, however, as it is the irreducible whole of authentic method itself. The
(Gadamerian) Socratic midwife welcoming the birth of new life and comforting the afflicted is
complemented by the (Derridean) Socratic gadfly afflicting the comfortable by creatively
destroying hidden preconceptions (Risser, 1989). Similarly, Kuhn (1970) distinguishes between
method as it is linearly presented in textbooks and method as it is lived by researchers
experiencing new forms of physis in the laboratory. Tracing the emergence of new methods
through the primary journal literature reveals the process of trial and error through which
phenomena come into the world as new entities.
Gadamer (1989, pp. 101-134) points to play as the most important clue to understanding the
nature of method. Echoing Husserl’s intention to attend to things themselves and Hegel’s
14
arguments against inauthentic externally-imposed methodologies, Gadamer elaborates a sense of
method as following along (meta-) the path (odos) described by phenomena as they are
experienced. The repetitive back and forth of questions and answers, experimental trials and
errors, playfully absorbs the observer into a participatory role and a partner in the creation of
meaningful representations (Toulmin, 1982).
The metaphor of Socratic maiuetics supports and informs nursing’s ontological midwives by
providing a fertile context for conceiving, gestating, birthing, and nurturing living meaning.
Caring in nursing is not only the field’s defining activity, caring is fundamental to human being.
The choice between peaceable negotiation and violent impositions of will hinges on caring
enough to try to create shared meaning, and begins from love (Fielding, 2003; Irigaray, 1984;
Marion, 2007; Ricoeur, 1967b).
Caring as the Midwifery of Living Meaning
For our purposes here, human and social capital are taken to include nurses’ own skills,
motivations, health, and trustworthiness, as well as that of their patients. Though human and
social capital have been a focus of interest of workers in the nursing context (Kritsotakis &
Gamarnikow, 2004; Lauder, Reel, Farmer, & Griggs, 2006; Royal, 2012), little or no attention
has been paid to how the very low efficiency of the respective markets might be improved.
Measurement costs are a primary source of this inefficiency (Barzel, 1982; Benham and
Benham, 2000), as their insurmountably high levels cause most human and social capital
investment decisions to be made on the basis of little, no, or mistaken information (Fisher, 2011,
2012; Goldberg, 2009).
The concept of capital is important to nursing because it focuses close attention on the
varied types of human, social, and economic value created in nursing (Covell, 2008; Gopee,
15
2002; Royal, 2012). Qualitative descriptions and evaluations of human and social capital are
important foundational steps to take toward creating uniform standards for quantifying their
value. Despite the meaning of the term “capital,” however, its application to date to human and
social assets (Becker, ; Coleman, 1988) remains an empty metaphor: amounts of skill,
motivation, health, or trust are not expressed in standard units in the way property and
commodities are, and neither can these forms of capital be associated with a known market
value. If intangible assets are to be priced in accord with their value, if they are to pay
appreciable returns on investment, and if they are to ever be included as significant factors in
economic models, they will have to be quantified. Authentic quantification embodying the
principles of ontological midwifery is one way vigilant attention can be focused on meaningful
representations.
How might caring human and social capital in nursing be conceived, midwifed, and nurtured
to a fuller maturity? The efficiency of capital markets depends on metrological standards like
common currencies and common product definitions well known for their value in reducing the
costs encountered in negotiating even the simplest transactions (Barzel, 1982; Benham &
Benham, 2000). Markets for property and manufactured goods are highly efficient because value
can be readily ascertained via socially sanctioned and scientifically developed universally
uniform standardized measures. Human and social capital, however, are needlessly dysfunctional
in highly inefficient markets because of the common but resolvable difficulties associated with
determining and representing value (Fisher, 2009, 2011, 2012). Better measurement is key to
overcoming these difficulties.
A place to start in exploring possibilities for ontological midwifery in nursing is suggested in
the realization that the physis experienced in the teaching, provision, and management of care
16
could be construed as the living DNA of a meaningful social body and collective intelligence.
Projecting and elaborating models of this kind involve positing abstract mathematical ideals as
heuristic fictions guiding inquiry (Butterfield, 1957; Ihde, 1991; Kuhn, 1961; Nersessian, 2002,
2006). Model-based reasoning processes in science are not qualitatively different from the way
words and concepts are used in everyday language (Nersessian, 2006, 2008; Fisher, 2004).
Models, like words, project unrealistically perfect conceptualizations of relationships between
distinct and separate unitary phenomena. No data or observations ever conform perfectly to the
models’ heuristic fictions. Perfect circles cannot be drawn, there are no mathematical pendula
made of a weightless string and a point-like mass, and there are no ability test data affected only
by the difficulties of the questions asked and the abilities of the persons measured.
Given such models and data that more or less fit them, instruments embody each separate
phenomenon’s perceptual profile and can do so in measuring units that are, first, experimentally
determined to be of a constant size, and, second, can be expressed in a standardized numeric
metric. These determinations of unit size and their standardization are facilitated by the Rasch
measurement models widely employed in educational assessment and professional licensure, that
are increasingly applied in health care research at large, and that have seen some limited use
within nursing research and practice.
Beyond the determination of invariant units, the support Rasch models offer for realizing the
goal of an ontological midwifery in nursing includes
the mapping of qualitative learning progressions and therapeutic continua useful in theory
development and in designing curricula and treatment programs as these are defined by
the invariant order of the item hierarchies established via instrument calibration;
the equating of different instruments experimentally shown to measure the same thing;
17
the adaptive administration of those instruments, such that items may be chosen for use
according to qualitative and/or quantitative criteria without compromising either the unit
or the error of measurement;
the theory-informed modification of existing instruments via the removal or addition of
items, again without compromising the comparability of the unit of measurement;
the removal of rater severity and leniency as factors influencing measures; and
the capacity to estimate measures in a standardized unit on the fly at the point of use, with
no need for data computerization, storage, analysis, and reporting.
Care for the quality, meaning, and practicality of measures is an important way of following
Nightingale’s advice as to putting “the patient in the best condition where Nature can heal”
(quoted in Watson, 1999, p. 258). The non-physical subtleties of energy and mood that must be
coordinated and mediated to create this condition inevitably must involve the matching of caring
skills with caring challenges, matching that could be more efficiently facilitated over the course
of nursing education and practice through the judicious construction of an array of well-tuned
instruments. Properly situated within a problem-focused methodological pluralism (Dawson,
Fischer, & Stein, 2006), care for the unity and sameness of the objects of healing conversations
can nurture the smallest seeds of possibility into fruitful trees of realized productivity.
18
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