Patent Abstract:
exemplary systems , methods and computer - accessible mediums can be provided that can , for example , receive information related to a detection of a pulse of a patient , and increase a pressure using a hardware arrangement to reach a first pressure level corresponding to the pulse no longer being detected . the pressure can be decreased to reach a second pressure level corresponding to the pulse being again detected , and the pressure can be maintained at the second pressure level to facilitate a venipuncture of the patient .

Detailed Description:
the “ systolic ” blood pressure is the peak arterial pressure occurring during contraction of the left ventricle of the heart . the “ diastolic ” blood pressure is the minimum arterial pressure which occurs during relaxation and dilatation of the ventricles of the heart as the ventricles fill with blood . the arterial diastolic pressure can approximate the pressure found in the venous circulation . the exemplary device can facilitate the optimization of tourniquet pressure between arterial systolic and diastolic pressures . the exemplary tourniquet ( e . g ., blood pressure cuff ) can be placed on the extremity and a pulse detecting arrangement can be placed distal to the cuff . the cuff can be inflated until the pulse oximeter signal can be lost , indicating that the cuff can be inflated to the arterial systolic pressure . the cuff can be deflated until the pulse oximeter signal can be present , and then the cuff pressure can be held at this point , which can be between the arterial systolic and the diastolic pressures . this can lead to progressive and rapid venous distension , which can facilitate a superior venipuncture . the exemplary device / apparatus can be designed and / or sized for different patient types ( e . g ., adult , pediatric , geriatric patients and / or obese patients ), and can include an inflatable cuff 105 ( e . g ., a blood pressure cuff ) in order to apply pressure at a patient &# 39 ; s limb where venous distention can be created by blocking venous flow , and can facilitate arterial flow . the inflatable cuff can be an adult - sized standard blood pressure cuff . as shown in fig1 , the exemplary device can include a pressure regulating unit / device / apparatus / system / arrangement , which can comprise a digital or analog circuit , as well as an air pump 110 ( e . g ., a miniature air pump ) and a solenoid valve 115 ( e . g ., a normally open solenoid valve ) and can be controlled by a microcontroller unit 120 (“ mcu ”) ( e . g ., an arduino controller ), in order to maintain the pressure applied by the cuff 105 , by determining the pressure through pressure gauge . the pressure regulating unit / device / apparatus / system / arrangement can increase , decrease or maintain the pressure at the cuff 105 by operating the solenoid valve 115 and the air pump 110 . the normally - open solenoid valve 115 can be and / or include an electromagnetic component that can close the airway when electrified . the exemplary valve 115 can be used to control the release of air from the cuff 105 ( e . g ., deflation ). the one - way valve can be , and / or can include , a mechanical component that , for example , may only facilitate the inflow of air to the cuff 105 . both the air pump 110 and the one - way valve 115 can control the inflation of the cuff 105 . table 1 below summarizes an exemplary pressure regulation by the solenoid valve and the air pump . the exemplary pressure regulating unit / device / apparatus / system / arrangement can include a pulse detecting unit / apparatus 130 ( e . g ., an infrared emitter and detector ), which can detect the patient &# 39 ; s pulse and , can provide feedback to the pressure regulating unit . the pulse detecting unit / apparatus can be coupled to an operational amplifier ( e . g ., op amp 145 ) for processing the signal . the exemplary pressure regulating unit / device / apparatus / system / arrangement can automatically determine , apply , and / or maintain pressure between the systolic and diastolic blood pressure in order to cause venous distention ( e . g ., by blocking venous flow while facilitating arterial flow ). the exemplary cuff 105 can be easily encircled around , and detached from , the patient &# 39 ; s limb in order to shorten the procedure duration for each venipuncture . the exemplary pressure regulating unit / device / apparatus / system / arrangement can also include an emergency pressure release mechanism 135 ( e . g ., a pressure release valve ) in order to avoid injury to the patient . ( see , e . g ., fig3 ). additionally , the exemplary pressure regulating unit / device / apparatus / system / arrangement can include a pressure release valve which can automatically release pressure above a predetermined amount . the applied pressure can be determined using an exemplary pressure sensor , which can initiate the release of the pressure through the pressure release valve when the predetermined amount of pressure is achieved or exceeded . the exemplary air pump and solenoid valve can be powered by power source 140 ( e . g ., a battery , such as a 9v ), and can be turned on and off by switch 150 . a lighting apparatus 155 ( e . g ., light - emitting diodes (“ leds ”)) can be included to indicate the operational status of the exemplary pressure regulating unit / device / apparatus / system / arrangement the exemplary pressure regulating unit / device / apparatus / system / arrangement can be lightweight ( e . g ., less than about 10 pounds ), and can be small ( e . g ., 20 cm × 15 cm × 10 cm excluding the exemplary pulse detecting unit and the exemplary cuff ). the exemplary pressure regulating unit / device / apparatus / system / arrangement can be inflatable at a rate of approximately 10 - 50 mmhg / sec , and can deflate at a rate of approximately 2 - 10 mmhg / sec . the exemplary pulse detecting unit can include a pulse sensor ( e . g ., a pulse oximeter ). when the pulse sensor detects blood flow , the cuff pressure can be increased above the systolic pressure , which can occlude both arterial and venous flows . the cuff pressure can be decreased to , and maintained at , a point between the systolic and diastolic pressures , where the resumption of blood flow can be detected . the exemplary pulse detecting unit can include an auscultatory apparatus ( e . g ., a sound sensor ). a sound sensor can be used to detect the korotkoff sounds produced when the cuff pressure can be between the systolic and diastolic pressure by applying gradual increases in the cuff pressure . the cuff pressure can be maintained as soon as the first korotkoff sound can be detected . the exemplary pulse detecting unit can include an oscillometric apparatus , and can apply the mean arterial pressure (“ map ”). a pressure of about 200 mmhg can be applied , which can be decreased gradually until oscillations of the artery can be detected by the pressure sensor . the pressure with the highest oscillation amplitude can be equivalent to the map . the pulse detecting unit can also include an indwelling arterial line . as shown in fig2 , the lighting apparatus 155 can indicate the operational status of the exemplary pressure regulating unit / device / apparatus / system / arrangement . for example , three leds ( e . g ., orange , green and red ) can be mounted on a top face of the exemplary pressure regulating unit / device / apparatus / system / arrangement . one or more leds ( e . g ., the orange ) can signify that the device can be in operation . another one or more leds ( e . g ., the green ) can signify a successful operation of the device and thus , venipuncture can be performed . further one or more leds ( e . g ., the red ) can signify errors in device operation . the exemplary pressure regulating unit / device / apparatus / system / arrangement can be operated by wrapping the exemplary cuff 105 around the upper arm of a patient that can be near the desired site of the venipuncture . the exemplary cuff can be tightened such that about 1 - 2 fingers can be inserted into the space between the patient &# 39 ; s arm and the exemplary cuff . the exemplary sensor ( e . g ., pulse oximeter ) can be placed on the thumb of the patient corresponding to the arm the exemplary cuff is placed on . the exemplary pressure regulating unit / device / apparatus / system / arrangement can be started and / or operated automatically . fig4 shows an exemplary flow diagram of a method for using the exemplary pressure regulating unit / device / apparatus / system / arrangement according to an exemplary embodiment of the present disclosure . for example , at procedure 410 , an infrared emitter can emit a signal in a fingertip 405 and detect a signal from fingertip 405 . at procedure 415 , exemplary filters and amplifiers can receive the raw signal from the infrared emitter and detector and process the signal . at procedure 420 , the initial peak - to - peak signal difference and threshold can be determined , and at procedure 425 , a new peak - to - peak signal difference can be determined and compared to a threshold . if the blood flow can be greater than the threshold , on a first detection by the infrared emitter and detector , the pump and valve can be turned on at procedure 440 and the pressure can be increased at procedure 445 . if the blood flow can be greater than the threshold , and it is the first detection by the infrared emitter and detector , then at procedure 450 , the pump can be turned off , the valve can remain on and the pressure can be maintained at procedure 455 to initiate a venipuncture at procedure 460 . if the blood flow can be less than the threshold at procedure 425 , then the pump and valve can be turned off at procedure 430 , and the pressure can be decreased at procedure 435 until the blood flow can be greater than the threshold . fig5 shows an exemplary circuit diagram of the exemplary pressure regulating unit / device / apparatus / system / arrangement according to an exemplary embodiment of the present disclosure . for example , the air pump and the solenoid valve can be connected to an inflatable cuff . the resistances of the resistors and the capacitances of the capacitors are shown in table 2 . exemplary part numbers of different components are shown in table 3 . the exemplary pressure regulating unit / device / apparatus / system / arrangement can use a reflective photoplethysmogram (“ ppg ”) sensor for pulse determination . the exemplary ppg sensor can detect the level of hemoglobin , which can be converted to current . beer - lambert &# 39 ; s law , absorbance and illuminance can be the principle equations used by the ppg sensor , which states that the absorbance of light can increase linearly with the concentration of the absorbing substance and the distance of the source of light . thus , for example : which can indicate the parameters in the beer - lambert &# 39 ; s law , where a can be absorbance , a can be the molar extinction coefficient , b can be the path length , and c can be concentration . for the exemplary ppg sensor , the exemplary path length can be constant , and can be equal to the depth of the fingertip the sensor is attached to . the absorbance can vary in relation to the concentration of the hemoglobin as the molar extinction coefficient of hemoglobin can also be a constant . even though whole blood does not strictly follow the law ( see , e . g ., reference 1 ), beer - lambert &# 39 ; s law can generally be valid when applied to hemoglobin at the fingertip , since red blood cells can pass one at a time through the capillary . where i transmitted can be the luminous intensity of the transmitted light and i incident can be the luminous intensity of the incident light . since the exemplary ppg sensor can be used to measure the reflected light , and the fingertip can be sealed , it can be assumed that lights can either be reflected or absorbed , thus , equation 2 can take the form of , for example : where i reflected can be the luminous intensity of the reflected light . the exemplary ppg sensor can use a photodiode to produce current based on the reflected light . the current can be produced according to the following exemplary equation : where i can be the current , r can be the responsitivity of the photodiode , and e v can be the illuminance of the light . the illuminance e v in equation 4 can be related to the luminous intensity by the following exemplary equation : where φ v can be luminous flux defined as i v ω , ωcan be a solid angle , which can be a two - dimensional angle that can have a magnitude as the area of a piece of a unit sphere ( see , e . g ., reference 2 ), and a can be the area the light shines to . by combining equations 4 and 5 , the output current of the photodiode can be obtained as a function of luminous intensity of the reflected light , which can be , for example : equation 1 relates concentration to absorbance , equation 3 relates absorbance to luminous intensity and equation 6 relates luminous intensity to current . by combining these three equations , the current can be obtained as a function of concentration , which can be , for example : in equation 7 , r and i incident can be the intrinsic properties of the infrared detector and emitter . a and ω can approximately be the projected area and the surface area of the emitter . the constants a and b can depend on the thickness of the fingertip , and absorbance of hemoglobin at the wavelength of the emitter . the hemoglobin concentration , c , can be a variable depending on blood flow of the subject . thus , the output current of the exemplary ppg sensor can vary with the hemoglobin concentration at the fingertip . when blood flow can be occluded , hemoglobin concentration c can remain constant , so a constant current can be obtained . by differentiating a time - varying current from constant current , occlusion of blood vessels can be determined . exemplary circuit analyses can be performed using ohm &# 39 ; s law on the three exemplary leds , the exemplary air pump and the exemplary solenoid valve . ohm &# 39 ; s law relates current and resistance to voltage , as shown in the following exemplary equation : three leds can be used in the exemplary device / apparatus for indication purposes . an exemplary led circuit is shown in fig6 . in this exemplary circuit , the led 605 can be connected in series with a resistor 610 . the power can be supplied to the circuit by the arduino &# 39 ; s output , which can be a constant 5 v signal 615 . since the led and the resistor can be in series , the current in the two components can be the same . when illuminated , there can be a voltage drop across the led . this voltage drop can be approximately 2 v . thus , the voltage across the resistor can be the arduino &# 39 ; s output subtracted by 2 v . using ohm &# 39 ; s law and the resistances for r 1 , r 5 , and r 6 ( e . g ., table 2 ), the currents i 1 , i 2 , and i 3 in led 1 , led 2 , and led 3 , respectively can be obtained as , for example : the exemplary maximum current the led can operate safely can be about 20 ma . ( see , e . g ., reference 3 ). as the values of i 1 , i 2 , and i 3 can be lower than the maximum current , it can be concluded that the led &# 39 ; s are working safely . two or more npn transistors can be used . npn transistors can have three pins , collector 705 (“ c ”), base 710 (“ b ”), and emitter 715 (“ e ”), as shown in fig7 . current can flow from c to e depending on the input of b . for a npn transistor , the current that flows into c ( i c ) can be the amplified version of the current that flows into b ( i b ). the dc current gain , h fe , can be defined as the ratio of i c over i b ( see , e . g ., reference 4 ). the h fe can signify a linear relationship between the input current i b and output current i c . the transistors in the exemplary pressure regulating unit / device / apparatus / system / arrangement can be used to control the air pump and the solenoid valve , as both components can utilize a large amount of current that cannot be obtained from the arduino alone . the exemplary transistors can be configured as switches that can control the air pump and the solenoid valve based on i b . switching transistors may need saturation , as only two states —“ on ” and “ off ” can exist for saturated transistors . ( see , e . g ., reference 6 ). saturation in a transistor can usually be done by inputting large i b such that i c becomes independent of the gain . thus , i c can remain constant as long as i b may not be zero ( e . g ., on ), and i c can become zero when i b can be zero ( e . g ., off ). the transistor can be saturated when i b can be approximately of the exemplary air pump and solenoid valve can be powered by a 9v battery 805 , and can be connected according to the transistor circuit shown in fig8 . the operating currents of the air pump and the solenoid valve can be about 380 ma and about 75 ma , respectively , when the power supply can be capable for outputting these currents . ( see , e . g ., references 7 and 8 ). thus , by modeling the air pump and solenoid valve as load resistors 810 , the corresponding i c values of the air pump and solenoid valve can be equal to the operating currents . the current i b can then be determined and can consequently be r b . to saturate transistors t 1 and t 2 , i b can be chosen as about 28 ma and about 7 ma , for the air pump and the solenoid valve , respectively . using ohm &# 39 ; s law ( e . g ., equation 8 ), the resistances of the resistors connecting to pin b ( r b ) can be determined as , for example : thus , an approximately 180ω resistor ( e . g ., r 2 ) can be connected to pin b of transistor t 2 for the air pump ( see e . g ., table 2 and fig5 ). an approximately 720ω resistance can be achieved by connecting two approximately 360ω resistors ( e . g ., r 3 & amp ; r 4 ) in series for the solenoid valve . ( i . d .). the air pump and the solenoid valve can be electromechanical components that contain solenoids ( e . g ., coils ). solenoids can induce electromotive force (“ emf ”), or voltage , when magnetic flux through the solenoid changes with time . this is known as faraday &# 39 ; s law . faraday &# 39 ; s law can be shown in the following exemplary formula ( see , e . g ., reference 9 ): where ε can be the induced voltage emf , n can be the number of loops , can be the derivative of magnetic flux ( φ b ) with respect to time ( t ). magnetic flux in equation 9 can be defined as the surface integral of the dot product of magnetic field , and the normal vector to an area where magnetic field lines pass through . ( see , e . g ., fig9 ). magnetic flux can be calculated using exemplary equation 10 . ( see , e . g ., reference 10 ). φ b = { right arrow over ( b )}· d { right arrow over ( a )}= ab cos ( θ ) ( 10 ) where { right arrow over ( b )} can be magnetic field with magnitude b , { right arrow over ( a )} can be the normal vector of the area magnetic field lines pass through with area a , and θ can be the smallest angle between the two vectors . as shown in fig9 , the solenoid can produce magnetic fields based on the current . the magnetic field produced by the solenoid can be calculated using equation 11 ( see , e . g ., reference 11 ), where , for example : where μ o can be the permeability of free space , l can be the length of the solenoid , and i can be the current in the solenoid . since the magnetic field produced inside of the solenoid can be parallel to the normal vector of the cross - sectional area of the solenoid ( see , e . g ., fig5 ), the surface integral and dot product in equation 10 can be simplified to exemplary equation 12 ( cos ( 0 °)= 1 ). combining equations 9 , 11 and 12 , an expression for induced voltage due to the change of current in the solenoid can be obtained as , for example : equation 13 can relate the change of current to the voltage induced by the solenoid . the term can be known as the inductance of the solenoid . according to this formula , when the air pump and the solenoid valve can be turned off , the current can suddenly decrease to zero . a sudden decrease in current can induce a positive emf ( ε ) with respect to the ground as shown in fig1 . these exemplary induced voltages , together with the 9v battery , can produce large currents toward the transistors , can enter the ground pin of the arduino , and can damage the two components . fig1 illustrates an exemplary circuit diagram of the exemplary current redirection by the exemplary pressure regulating unit / device / apparatus / system / arrangement . one solution to avoid the potential damage of the prototype due to the induced voltages can be to connect a diode parallel to the exemplary solenoid ( see , e . g ., reference 13 ) ( e . g ., air pump and solenoid valve ) as shown in fig7 . the diodes ( e . g ., d 1 and d 2 shown in fig5 ) connected across the solenoid valve and the air pump can be termed protective diodes and can complete the short circuits that redirect the induced currents back to the solenoids , thus preventing damage to the rests of the circuitry . the exemplary pressure regulating unit / device / apparatus / system / arrangement can be used to apply pressure to the patient &# 39 ; s arm through inflation of the inflatable cuff by air . by assuming air as an ideal gas , the cuff pressure can be predicted using the ideal gas law , which can be , for example : where p can be the absolute pressure , v can be the volume , n can be the number of molecules , r can be the gas constant , and t can be the absolute temperature . while encircling a patient &# 39 ; s arm , the inflatable cuff can only hold a specific volume . when this volume can be reached , the number of molecules can increase due to the input of air by the pump while the volume remains unchanged . if the air pump &# 39 ; s volumetric flow rate can be q , the gauge pressure of the inflatable cuff , p , can be calculated using the following exemplary formula derived from the ideal gas law : q can be the volumetric flow rate , p l can be the load pressure , and p atm can be the atmospheric pressure . the term qρt in equation 15 can be the number of molecules pumped into the inflatable cuff in time t due to volumetric flow rate of q ( e . g ., qρ can be molar flow rate of air ). p l can be the load pressure defined as the pressure that the air pump operates against . it can also be that the pressure remains in the cuff due to the previous pumping . because the pressure in the ideal gas law can be the absolute pressure , atmospheric pressure p atm can be subtracted to obtain the applied pressure , which can be a gauge pressure . since air can be assumed to be an ideal gas , the term rtρ can be the same as atmospheric pressure , and the two terms can cancel out . equation 15 can then be simplified to , for example : if the volumetric flow rate q of the air pump can be known , the applied pressure can be calculated or otherwise determined using equation 16 . however , the volumetric flow rate can be a function of load pressure p l . the exemplary air pump can have a volumetric flow rate curve under the zero - load current of 155 ma . ( see , e . g ., reference 8 ). this curve can follow a typical exponential decay and can be approximated by the following exemplary equation : in the exemplary device , the zero - load current can be about 380 ma . if it can further be assumed that the volumetric flow rate curve can maintain its shape , but the magnitude can change linearly with the zero - load current , the volumetric flow rate for 380 ma can be obtained as , for example : equation 18 is plotted in fig1 . when the load pressure , or pressure that exists inside the cuff due to previous pumpings increases , the volumetric flow rate can decrease . by substituting equations 18 into equation 16 , the applied pressure as a function of the load pressure , or the pressure existing in the cuff , can be obtained as , for example : because of the stepwise application of pressure in the exemplary device , equation 19 can be used to estimate the newly applied pressure to the arm using the existing pressure in the cuff ( p l ). blood flow through arteries and veins can be determined by utilizing the conservation of mass principle , which states that the rate of accumulation of mass in a control volume can equal the difference between the flows of mass into and the mass out of the control volume , as shown in fig1 . the flow of blood can be assumed to be a pressure - driven laminar flow of an incompressible newtonian fluid ( e . g ., blood ) through a cylindrical tube ( e . g ., blood vessel ). such a case can be known as the poiseuille flow . the flow can be unidirectional along the longitudinal axis . when it can be fully developed , the velocity of blood can be a function of radius only , and can be expected to exhibit maximum velocity with a radial symmetry about the centerline . the velocity profile under these assumptions is shown in fig1 a , which illustrates laminar flow of a newtonian fluid through a cylinder , and 14 b , which illustrates a momentum balance on a differential volume . since the flow can be steady , the sum of all forces can be equal to zero , and the only relevant forces can be pressures and shear stresses . under these assumptions , the navier - stokes equation in the z - direction ( e . g ., exemplary equation 20 ) can be simplified to exemplary equation 21 . where p can be pressure , z can be the longitudinal direction , μ can be viscosity , r can be the radial direction , and v z can be the velocity in the z - direction . in equation 21 , pressure p can be a function of z , and velocity v z can be a function of r . the only situation where the sum of the derivatives of a function of z and a function of r can be zero is when they both can be constants . by integrating the pressure gradient as a constant with boundary conditions (“ bc ”), the following , for example , can be obtained : where p o can be the pressure at the origin ( e . g ., the heart ), l can be the distance from the origin , and p l can be the pressure at a distance l ( e . g ., the extremity ). by taking the derivative of equation 22 with respect to z , and substituting the expression into equation 21 , the differential equation of v z can be obtained as , for example : where c 1 and c 2 can be constants of integration . by using the following boundary conditions , the velocity profile v z can be obtained as , for example : the volumetric flow rate of blood q b ( e . g ., equation 27 below ) can be obtained by integrating the velocity over the cross - sectional area of the blood vessel . thus , for example the exemplary pressure regulating unit / device / apparatus / system / arrangement can be used to apply pressure between the systolic and diastolic pressures . the brachial artery and the cephalic vein are the two main blood vessels in the upper arm that can receive the applied pressure . the diameter of the brachial artery can be approximately 3 . 52 mm , ( see , e . g ., reference 16 ), and the diameter of the cephalic vein can be about 2 . 4 mm . ( see , e . g ., reference 17 ). the cephalic vein can be assumed to be occluded when the applied pressure can be higher than the diastolic pressure . the brachial artery can be assumed be occluded if the applied pressure can be higher than the systolic pressure . the radii can be described using the following exemplary equations for the brachial artery and the cephalic vein , respectively , by assuming the radii decrease linearly when the applied pressure can be increased : the radii can be redefined to zero when the applied pressure can be greater than the systolic pressure , and the diastolic pressure for the brachial artery and the cephalic vein , respectively , since negative radii can be physically impossible . the flow rate in equation 27 can assume blood to be a newtonian fluid . however , blood &# 39 ; s behavior can depend on shear rate ( e . g ., velocity gradient ). a more sophisticate model of blood flow can be shown as , for example : ( see , e . g ., reference 18 ) where r can be radius of the blood vessel , p can be pressure , η n can be blood viscosity at high shear rate , l can be the length of the blood vessel , τ o can be yield stress of blood , and τ w can be shear stress at the wall of the blood vessel . the inflatable cuff can be wrapped around the upper arm to apply a pressure . the pressure the exemplary device / apparatus can apply can be approximately 220 mmhg depending on different individuals . in the presence of an exerted pressure , the walls of blood vessels can contract . therefore , the blood vessels can resist the contraction force with a hoop stress in the circumferential direction to avoid any vessel damage . the hoop stress can have vital physiological significance . it can be the primary force in regulating blood vessel wall thickness and residue stress , in response to blood pressure and hypertension . ( see , e . g ., reference 19 ). assuming that the blood vessels can be very thin , the hoop stress can be calculated using , for example : ( see , e . g ., reference 20 ) where τ θ can be the hoop stress , p can be pressure , r can be radius , and t can be thickness . the exemplary dimensions for the brachial artery and the cephalic vein are summarized in table 4 below . the hoop stresses can be calculated using equation 31 at a maximum pressure of about 220 mmhg the hoop stresses calculated from previous experimental studies are included in the table as references to determine the accuracy of the exemplary calculation . one of the purposes of the hoop stress analysis can be to ensure that the maximum applied pressure of about 220 mmhg does not cause any damage to blood vessels . according to one study , most human arteries &# 39 ; can yield hoop stresses which can be in the order of 10 5 pa ( e . g ., 100 kpa ). ( see , e . g ., reference 19 ). in another study , most mammalian arteries can be expected to exert hoop stress between about 240 kpa and about 280 kpa at about 100 mmhg . ( see , e . g ., reference 23 ). in the exemplary analysis , the brachial artery can exert about 147 . 5 kpa at the maximum pressure of about 220 mmhg . since 147 . 5 kpa can be in the order of about 10 5 pa and much less than about 240 kpa , the exemplary device does not cause any damage to the brachial artery . similarly , the cephalic vein can be found to exert a hoop stress of about 245 kpa at the mean arterial pressure under normal physiological conditions . ( see , e . g ., reference 22 ). in the exemplary analysis , the hoop stress for cephalic vein can be calculated to be about 26 . 1 kpa at the maximum pressure of about 220 mmhg . since 26 . 1 kpa can be much less than about 245 kpa , the pressure exerted from the exemplary device will not damage the cephalic vein . fig1 shows a block diagram of an exemplary embodiment of a system according to the present disclosure . for example , exemplary procedures in accordance with the present disclosure described herein can be performed by a processing arrangement and / or a computing arrangement 1502 . such processing / computing arrangement 1502 can be , for example , entirely or a part of , or include , but not limited to , a computer / processor 1504 that can include , for example , one or more microprocessors , and use instructions stored on a computer - accessible medium ( e . g ., ram , rom , hard drive , or other storage device ). as shown in fig1 , for example , a computer - accessible medium 1506 ( e . g ., as described herein above , a storage device such as a hard disk , floppy disk , memory stick , cd - rom , ram , rom , etc ., or a collection thereof ) can be provided ( e . g ., in communication with the processing arrangement 1502 ). the computer - accessible medium 1506 can contain executable instructions 1508 thereon . in addition or alternatively , a storage arrangement 1510 can be provided separately from the computer - accessible medium 1506 , which can provide the instructions to the processing arrangement 1502 so as to configure the processing arrangement to execute certain exemplary procedures , processes and methods , as described herein above , for example . further , the exemplary processing arrangement 1502 can be provided with or include an input / output arrangement 1514 , which can include , for example , a wired network , a wireless network , the internet , an intranet , a data collection probe , a sensor , etc . as shown in fig1 , the exemplary processing arrangement 1502 can be in communication with an exemplary display arrangement 1512 , which , according to certain exemplary embodiments of the present disclosure , can be a touch - screen configured for inputting information to the processing arrangement in addition to outputting information from the processing arrangement , for example . further , the exemplary display 1512 and / or a storage arrangement 1510 can be used to display and / or store data in a user - accessible format and / or user - readable format . according to further exemplary embodiments of the present disclosure , it can be possible to provide certain exemplary changes to the system according to the exemplary embodiment of the present disclosure . for example , it can be possible to utilize a standard 9v alkaline battery , although a use of a 9v lithium battery can provide an extended capacity ( e . g ., which can be as much as 3 times ) greater than a 9v alkaline battery . in addition , for example , it can be possible to provide a configuration which can effectuate a reverse battery protection . a further exemplary solenoid valve can be provided which can have a higher voltage capacity , and which can lower power consumption . further , instead of or together with the external release valve , it can be possible to utilize an integral release valve . in additional exemplary embodiments of the present disclosure , another exemplary circuit board can be provided for the use with the exemplary system according to the present disclosure . for example , as shown in fig1 , such exemplary circuit board can be laid out for a top mounted power switch and led indicators , and can be placed in a serpac enclosure , as shown in fig1 a and 17b ( providing top front and top rear views thereof ). holes can be machined to provide access to the internal works . nomenclature can be silkscreened onto the enclosure . a 9v battery compartment on the rear of the exemplary enclosure provides for battery replacement without disassembly . thus , according to such exemplary embodiment of the present disclosure , as illustrated in fig1 , a standard blood pressure cuff 1805 can be used with the exemplary system 1810 shown in fig1 , 17a and 17b . for example , the pump bulb can be removed , and the release valve and cuff can be attached using luer connectors . the pressure gauge can be attached to the cuff . the finger sensor can be replaced by a nelcor compatible spo 2 adult finger unit and attached to the pst via , for example , a standard 9 pin serial port connector or using other known connectors . fig1 shows an exemplary schematic diagram of the exemplary circuit board illustrated in fig1 , and fig2 a - 20h shows various view of sections of the layout of the exemplary printed circuit . the foregoing merely illustrates the principles of the disclosure . various modifications and alterations to the described embodiments will be apparent to those skilled in the art in view of the teachings herein . it will thus be appreciated that those skilled in the art will be able to devise numerous systems , arrangements , and procedures which , although not explicitly shown or described herein , embody the principles of the disclosure and can be thus within the spirit and scope of the disclosure . various different exemplary embodiments can be used together with one another , as well as interchangeably therewith , as should be understood by those having ordinary skill in the art . in addition , certain terms used in the present disclosure , including the specification , drawings and claims thereof , can be used synonymously in certain instances , including , but not limited to , for example , data and information . it should be understood that , while these words , and / or other words that can be synonymous to one another , can be used synonymously herein , that there can be instances when such words can be intended to not be used synonymously . further , to the extent that the prior art knowledge has not been explicitly incorporated by reference herein above , it is explicitly incorporated herein in its entirety . all publications referenced are incorporated herein by reference in their entireties . the following references are hereby incorporated by reference in their entirety . steinke j m . role of light scattering in whole blood oximetry . ieee transactions on biomedical engineering . 1986 ; 33 : 294 - 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