Abstract:
A device for monitoring and correction of a functional condition of a human body on the basis of measurement of thresholds of temperature painful sensitivity (TPS) of acupuncture points (AP). The device includes a diagnostics and treatment module, a control and communication block and a server, connected by bi-directional data channels. The module includes a handle with an autonomous power unit and a means of reception/transmission. The module is supplied by an element of thermal influence on AP in the form of an infrared LED connected to a current generator, a radiation indicator, a switch, inputs/outputs and a microcontroller. The control and communication includes a mobile phone or a computer of the patient with a related function of data reception/transmission, display of the data and control of the module, by means of inputting of a resident program. The handle serves as the peripheral indicator of a condition and the device of influence with the low price for the patient, and all processing of the address individual information of each patient is assigned to the server.

Description:
FIELD OF THE INVENTION 
     The present invention relates to dispensing daily doses of medications. More particularly, the present invention relates to the customization and modification of daily dosages of medication for administration to the patients. 
     DISCUSSION OF THE RELATED ART 
     Medication management systems play an integral part of long-term care facilities. For example, companies recognized the need for pharmacies to provide customers a secure, affordable and fully customized solution for medication management. Most patients rely upon the conventional process of a doctor and a pharmacist to make decisions about their dosing of medications. 
     For convenience and safety, pharmacies provide the service of prepacking medications for patients using medicine trays. This process includes looking at all the medications of a patient, and determining how often a patient needs to take the medications. The medications are placed within predefined slots, such as having slots for morning and afternoon. Medications in the morning slots are taken in the morning, and so on. 
     A patient may take a medication dosage based on the predefined medication slots that are filled by a pharmacist in the respective trays. For example, four slots per day (morning, noon, evening and night) are configured within the tray. This example is shown in  FIG. 1 . Pack  102  includes various medications that are taken at different times during the day. As can be seen, the medications are identified graphically to help the patient visualize when to take them. Pack  104  shows additional medications taken during the day. As can be seen, these medications may differ from the ones within pack  102 . Pack  106  and pack  108  also show medications taken during different times of the day. Thus, a patient having the name of John Feelgood may use these four packs within a week, as can be seen. 
     The medications are placed within their respective slots so that a patient merely takes the medications in the slot at the appointed time. The patient does not need to count out medications or try to guess if the last dosage was missed. Many facilities and organizations assist patients by pre-filling the slots within medication packs. 
     Many patients prefer to take their medications in a manner that fits their lifestyle. This flexibility results in improved compliances, improved efficiency, reduced side effects, and reduced inconveniences. In fact, it may be said that the same medication regimen for two or more patients may be taken in a different manner by each patient. When a doctor advises patients to take a medication twice a day, one patient may take the medication in the early morning and the other dosage at bedtime. Meanwhile, another patient may take the same dosages after breakfast and before dinner. 
     Thus, patients should be given the choice on when to take their dosages. A doctor or a pharmacist, however, may need to verify the dosing changes requested by a patient. For example, some medications are best taken before meals while others should be given with meals. Some medications are best taken in the morning while others are best taken at bedtime. This process is manual, cumbersome or non-existent. 
     Data is shared with pharmacies of common ownership, especially convenience for patients as they can fill prescriptions at any of these pharmacies. A patient, however, cannot allow their data to be accessible at any pharmacy for dispensing without regard to ownership or applicable software systems. Further, patients do not want to deal with multiple websites and services to indicate their preferences for making the dosage packs. 
     SUMMARY OF THE INVENTION 
     To address these issues, the disclosed embodiments allow patients to securely modify the dosage regimen relying on novel technology and automated systems that provide tracking, security, accountability and efficiency. The disclosed embodiments give an opportunity to a patient to easily alter a schedule of intake of medications while receiving approval from the doctor/pharmacist through supported channels of communications. The disclosed embodiments also allow manual or automated dispensing of the doses at the dispensing place, i.e., pharmacy, of choice. 
     The disclosed embodiments set forth a novel method or process of modifying or customizing the dispensing of the daily doses of medications to patients. The disclosed embodiments also include a process of customizable dose modifications by patients, their caregivers and doctors to improve compliance and efficacy of the medications while reducing possible side effects. The patient may access a database for the pharmacy, the prescriber, the central store prescription database or the insurance company so that the patient may view and modify the dosage or timing of their medication. The patient also may report or log any communications related to the medication. 
     The disclosed embodiments also provide for a method of automating the process of packaging the medications through technology and a network of pharmacies in addition to manual dispensation. The disclosed embodiments also provide a method for packaging medication that displays detailed times for each dosage, thereby resulting in a user-friendly and an efficient packaging system. 
     The disclosed embodiments also include a unique robotics system that allows the automation of the packs. The disclosed embodiments also show a distinct approach for optimizing the packaging of medications to significantly reduce the costs of packaging per unit pack per patient. This feature lowers costs for health care to providers and consumers. 
     The disclosed embodiments also set forth an innovative process wherein the patient&#39;s medication records can be uploaded centrally with their dosing preferences. This feature allows a patent to place a request from any place to any pharmacy, regardless of the ownership of the pharmacy or facility, or any applicable computer system. The patient also may obtain the medication in a preferred dosing or packaging. 
     The disclosed embodiments may store the default timings of medication allowed for best efficacy. Some medications, for example, may only be taken at night. Thus, if a patient chooses to take a dose in the morning, then the system can require the prescriber&#39;s or pharmacist&#39;s approval. If a patient chooses a dose time in the allowable range of time, then no professional intervention may be required. Similar data can be maintained for two drugs, which interact if taken together, or for preferred times in order to dismiss any worry. 
     A computer-implemented method for packaging medicine doses for a patient is disclosed. The computer-implemented method includes modifying or customizing a dosage schedule for at least one medicine. The patient selects a day or time to receive a dose of the at least one medicine. The computer-implemented method also includes uploading the modified or customized dosage schedule for approval by a doctor, caregiver or pharmacy using a device connected to a network. The computer-implemented method also includes receiving the approval for the modified or customized dosage schedule. The computer-implemented method also includes dispensing the at least one medicine into a customized or modified medicine pack according to the dosage schedule. 
     A robot packing system to create a customized or modified medicine pack also is disclosed. The robot packing system includes a drug cartridge having at least one medicine. The robot packing system also includes a hopper configured below the drug cartridge to receive the at least one medicine. The robot packing system also includes a drop tray having a door to receive the at least one medicine and to create a vial of the at least one medicine. The robot packing system also includes a transfer plate to receive the vial released from the drop tray and to place the vial into a holder according to a customized or modified dosage schedule. The robot packing system also includes a sealing station to seal the holder to form the medicine pack. The medicine pack is configured to provide the at least one medicine according to the dosage schedule. 
     A method for creating a medicine pack according to a dosage schedule also is disclosed. The method includes modifying or customizing the dosage schedule by a patient selecting slots for a day or time to take a dose of medicine. The method also includes sending the dosage schedule over a network to a doctor, pharmacy or a caregiver. The method also includes receiving approval for the dosage schedule. The method also includes packaging the medicine into a medicine pack according to the dosage schedule. 
     A patient-pharmacy medicine management system also is disclosed. The patient-pharmacy medicine management system includes a device used by a patient to customize or modify a dosage schedule, and to upload the dosage schedule to a network. The patient-pharmacy medicine management system also includes a medicine dispensing system connected to the network and configured to create a medicine pack according to the dosage schedule. An approval is received by the medicine dispensing system by a caregiver for the dosage schedule. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The accompanying drawings are included to provide further understanding of the invention and constitute a part of the specification. The drawings listed below illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention, as disclosed by the claims and their equivalents. 
         FIG. 1  illustrates a conventional packaging configuration. 
         FIG. 2  illustrates a system for packaging medications according to the disclosed embodiments. 
         FIG. 3  illustrates a robot packing system according to the disclosed embodiments. 
         FIG. 3 a    illustrates another configuration of the robot packing system according to the disclosed embodiments. 
         FIG. 4  illustrates a flowchart customizing the medication dose by a patient or other party according to the disclosed embodiments. 
         FIG. 5  illustrates an improved packaging configuration of patient-customized medications according to the disclosed embodiments. 
         FIG. 6  illustrates a sample of the labels used in a medication dosage dispensing system according to the disclosed embodiments. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Aspects of the invention are disclosed in the accompanying description. Alternate embodiments of the present invention and their equivalents are devised without parting from the spirit or scope of the present invention. It should be noted that like elements disclosed below are indicated by like reference numbers in the drawings. 
       FIG. 2  depicts a system  200  for packaging medications according to the disclosed embodiments. The disclosed embodiments relate to methods and processes to allow customizable dose modification by patient  102 , their caregivers and physicians  110  to improve compliance and efficacy of medications while reducing side effects. 
     As shown, system  200  includes patient  102 . The term “patient  102 ” may refer to any person or entity that orders and makes medical decisions. Preferably, patient  102  refers to a patient, but also may refer to a third party entity that makes decisions on behalf of a patient. It may be a caregiver, such as a nurse or aide. Patient  102  also could refer to a family member or trusted individual having the authority to make medical decisions on behalf of the patient. 
     Patient  102  uses device  104  to access robot packing system  208  at pharmacy  206 . Device  104  may be any device capable of connection to a network and displaying information received over the network. For example, device  104  may connect to the internet to allow patient  102  access to other entities having IP-addressable devices. Preferably, device  104  uses a graphic user interface to display information to patient  102  and to receive input on customizing or modifying doses, as disclosed below. Device  104  may include a smartphone, tablet, laptop, personal computer, and the like. 
     In an alternative embodiment, patient  102  may view information within pharmacy  206 , in person. Patient  102  can tell a pharmacist how he or she would like to customize their medication dosage. Further, patient  102  may fill out a form or paper to customize or modify medication dosage. Patient  102  also may do this at a doctor&#39;s office or anyplace else that provides medical services, such as a hospital or rehab location. In a hospital, patient  102  may inform a caregiver, who then provides the appropriate information to robot packing system  208 . 
     Thus, patient  102  views the medication information online or in person. Patient  102  has the option to modify the dosage timing of the medication according to their preferred lifestyle or preferences. Patient  102  may drag and drop medicines into appropriate time slots, and modify the time with a click, tap, voice command, double click and the like. This customization will be effective once the pharmacy, or the doctor, approves the new schedule if approval is deemed to be necessary. 
     Robot packing system  208  may reside in pharmacy  206 , but also may be located within any location. Once the customization instructions from patient  202  are received. Robot packing system  208  retrieves medicine(s) from inventory  214 . Inventory  214  may be medicine, over-the-counter drugs or medical supplies. Typically, these materials are controlled from public consumption and regulated. 
     Robot packing system  208  then places medicines specified in the request from patient  202  into packs to generate medication pack  216 . Medication pack  216  may be sent or given to patient  202 . 
     Approval from physician  210  may be sought prior to customization or modification of the medicinal dosages. Pharmacy  206  or robot packing system  208  may send a message, text, or other form of communication to physician  210  that approval is needed for the change in medicine. Once approval is given, then robot packing system  208  may be activated. The processes and methods related to these components are disclosed in greater detail below. 
     System  200  includes server  216 , which may be connected to robot packing system  208 . Server  216  may stores software or instructions to operate robot packing system  208 . It also may store the customizations and modifications for retrieval by patient  202 . Records and other information may be stored at server  216 . Other pharmacies may access server  216  as well. 
     Robot packing system  208  is disclosed in greater detail by  FIG. 3 . Robot packing system  208  may be located within a pharmacy, hospital, rehabilitation center and the like where medicines are dispensed. Once the customization or modification of medicine dosage is received, then the medication packs may be assembled according to the desired configuration. 
     Drug cartridges  302  are located at the top of robot packing system  208 . Drug cartridges  302  may include the medicines requested by patient  202  and selected from inventory  214 . Drug cartridges  302  also may be located on the sides. This configuration gives flexibility of easy operation for the online changing of the drug cartridges. Drug cartridges  302  also may be known as drug trays. 
     Drug cartridge  302  may be rectangular with a cylinder underneath. Medicines slide into several channels on the edges of the cylinder of drug cartridge  302 . Rotation of the drug cartridge causes channels to pass over a hole. An optical sensor ensures only one pill, or medicine, drops as a channel is over a hole. These commands relate to the customizations or modifications selected by patient  202  according to the disclosed embodiments. 
     Drug cartridge  302  also includes radio frequency identification (RFID) tags for easy inventor and identification. The RFID relates to a different drug or medicine. This allows the robot to check that the medicine dropping from drug cartridge  302  matches the one indicated by the disclosed customization or modification. RFID sensors of the robot detect which canister, or cartridge, is where within the system. A light emitting diode (LED) may be included and flashes when drug cartridge  302  is empty. A brushed direct current (DC) motor may move cartridges. 
     The medications fall from drug cartridges  302  into hopper  304 . Hopper  304  may go from a wide opening to a narrow bottom opening. The bottom opening may be a square having a length of about 4.25 inches to accommodate placing medications into drop tray  304 . From hopper  304 , the medications fall to drop tray  306 . Drop tray  306  includes a door  308  so that the medicines fill up the tray before the next step. Hopper  304  channels medications to drop tray  306 . Hopper  304  may be acrylic and of a clear or a transparent color to allow a user to look into it. 
     Drop tray  306  may be of a black or dark color with a matte surface. This feature allows drop tray  306  to be used for image processing. A camera takes photos or video of the medicines as they accumulate on drop tray  306 . Drop tray  306  also holds the medicines temporarily while an x-y table moves to the required slot while the medicines are dropping. This increases the speed of packaging the medicines. The disclosed embodiments do not have to wait for the required slots to be in position before dropping the medicines. This configuration also may include a servo motor to open and close door  306  along with a door shaft connected thereto. A drop door box may enclose this entire assembly. 
     The above configuration also may include a small hopper to receive the medicines dropped by drop tray  306 . A tunnel may be connected to the small hopper. The tunnel has a certain height that prevents medicines from bouncing back into the small hopper when it is dropped into the pre-fill tray. The tunnel includes a tunnel wall that prevents medicines from slipping into another slot. The tunnel opening should be smaller than the slots in the pre-fill tray, so the tunnel wall covers the top of a slot opening to prevent medicines from falling or bouncing out. 
     The disclosed configuration also may include a pre-fill tray that includes a specified number of slots. The preferred number may be about 28 slots. The medicines are held here until dropped into the blister packs. The pre-fill tray includes a pre-fill tray door to hold the medicines. 
     When cavity holder, or blister pack,  312  moves beneath transfer plate  312 , the pre-fill tray door opens to drop medicines  310 . Preferably, medicines  310  are a plurality of pills. Medicines  310  also may be known as medicine doses. As stepper motor may drive the pre-fill tray door. Transfer plate  312  allows robot packing system  208  to fill many different packs or vials. Transfer plate  312  packs cavity holder  312 . The dimension of slots in the pre-fill tray is different from the dimension of slots in the blister pack. So transfer plate  312  is needed. Transfer plate  312  has small tubes which will direct medicines  310  to fall from the pre-fill tray into the slots of the blister pack, or cavity holder  312 . 
     Once medicines  310  fill cavity holder  312 , the package is forwarded to sealing station  316 . A round table configuration may facilitate this process. The round table may have a diameter of about 56 inches and driven by a stepper motor. It may include about 5 sections/tray slots. Sealing station  316  may located on the right side of the round table. One or more infrared photodiodes may ensure accurate turning of the round table. The photodiodes also detect the packs on the round table, and automatically raises a warning if a pack is not present when medicines are dropped. 
     The round table also includes manual controls to manually turn the table as needed. The controls may move the table left or right. The manual controls also include a manual control for heat sealing the package. Thus, an operator may perform the process manually as opposed to automatic. The controls also include an emergency heat seal release. 
     The package is heat sealed in order to keep the medicines stable and to prevent spilling the contents. Sealing station  316  does this. Sealing station  316  may be use a step-based actuator. An emergency release button may be included on sealing station  316  along with an openable cover to prevent accidents. A laser curtain on openings of the cover detects when a hand is near in order to shutdown and prevents injury. The package is then sent to printing station  318 . Printing station  318  retrieves the instructions for the customization or modification from patient  202  from server  216 . After this, pack  216  is made available at the pharmacy, hospital and the like for pick up by patient  202 . 
     The disclosed embodiments also include a manual packaging process for preparing packages for medicine dispensing. This process may be used by those pharmacists who do not have robot packing system  208 . The pharmacist may dispense the medication manually upon the approval of the modified dosage regimen. 
       FIG. 3 a    depicts another embodiment of robot packing system  208 . The system shown in  FIG. 3 a    further illustrates the embodiments and features disclosed above. As can be seen, system  208  includes the system after the medicine is released from the canister, or drug cartridge  302  of  FIG. 3 . Here, main hopper  1  receives the medicine and channels them to drop door  2 . Camera stand  1   a  supports camera  1   b , which may be used for quality assurance or counting operations, as disclosed above. Main hopper  1  may be transparent. 
     Medicines, preferably in the form of pills, accumulate on drop door  2 . Servo motor  3  opens and closes drop door  2  when packing system  208  gives the instructions to release the medicines. Door shaft  4  connects servo motor  3  and drop door  2  and actuates drop door  2 . Drop door box  5  is a square box that encloses the drop door assembly. 
     Small hopper  6  channels medicine released from drop door  2  into small tunnel  7 . Tunnel wall  8  prevents medicine from jumping into another slot or falling away. Pre-fill tray  9  holds medicines before they are dropped into the pack. Pre-fill tray doors  10  holds the medicines until instructions are received from robot packing system  208  to release. Stepper motor  11  drives pre-fill tray doors  10 . Doors  10  release when transfer plate  12  is above the medicine pack and below pre-fill tray  9 . 
     Other configurations of robot packing system  208  may be used according to the disclosed embodiments. Transfer plate  12  may reflect the customized or modified dosage schedule desired by patient  202 . 
     Further according to the disclosed embodiments, vials may be used in the above-disclosed robot packing system. A vial is basically a bottle or a container that contains only one type of drug. For example, if the prescription calls for Erythromycin as the only medicine on the dosage schedule for a period of time (such as two weeks), then the medicine may be placed into a vial. Instead of putting all the pills of Erythromycin in a pack that has compartments and different bubbles, the disclosed embodiments put it all in one bottle (a vial) and label the bottle. Thus, a vial is a container that does not have different compartment and does not separate the tablets. When there are multiple medications as part of the prescription which differ in times/days and quantity and type, then it makes sense to put these medications into a bubble pack. A vial or vials also may be used in conjunction with the disclosed medicine packs. 
       FIG. 4  depicts a flowchart  400  customizing the medication dose by a patient  202  or other party according to the disclosed embodiments. Step  402  executes by compiling information from the insurance records of patient  202 . Insurance claims and histories may be made available for use by the disclosed embodiments. Step  404  executes by compiling or accessing medical records (“Rx records”) for patient  202 . The medical records may be made available subject to HIPAA rules and regulations, as well as federal and state law, or any laws and regulations governing the use of medical records and privacy. 
     Step  406  executes by compiling or accessing prescriber records. These records may be located at the pharmacy or across databases for large pharmacies. Patient  202  may switch medical providers, and, thus, the medical records of step  404  may not be totally available. Patient  202 , however, may use the same pharmacy, so these records provide more consistent or comprehensive information than medical records. Step  408  executes by compiling central store records for patient  202 . 
     Step  410  executes by receiving input from patient  202  regarding customizing or modifying a medical dosage. A caretaker or other entity/person may perform this step. Patient  202  may provide this information via a web-enabled device, as disclosed above, or through the phone, such as a call-in feature, or a text (SMS) message. Patient  202  enters the desired information, or makes it available to the disclosed embodiments of the present invention. 
     Step  412  executes by accessing the medicine store, also called MyDoses, by patient  202  with their request. Alternatively, patient  202  may access the system configuration shown in  FIG. 2 . Step  414  executes by patient  202  viewing his or her medical dosages. The patient may view the dates and times of the dosages, as shown in greater detail below. 
     Step  416  executes by modifying the preferred dose time of the doses pertaining to patient  202 . If no medical doses are set up, then patient  202  may customize the doses for a new order. Patient  202  may manipulate a graphical user interface or an application to set the dose times. 
     Step  418  executes by determining whether approval is required by physician  210  or some other entity. For example, a health insurance provider may require approval before allowing medicines to be dispensed. If no approval is needed, then flowchart  400  moves to step  424 . If approval is needed, then step  420  executes by determining whether the customized or modified dosage is approved by physician  210  or other entity. If not approved, then step  422  executes by stopping and notifying patient  202 . The dispensing process is halted until this issue is resolved. 
     Step  420  also may compare the desired doses to the records and information compiled in step  402 - 408  to make sure that the customized or modified doses do not cause any potential medical problems, and that the doses are compatible with each other. Problems may be identified here, and patient  202  or physician  210  or the pharmacist alerted. 
     If step  420  determines that the customization or modification is approved, then flowchart  400  moves to step  424 . Step  424  executes by approving the medical dispensing customization or modification for dispensing. Pharmacy  206  may do this. Step  426  executes by dispensing the medicine according to the disclosed embodiments. Robot packing system  208  may dispense and create the medicine packages as disclosed above. 
     Step  428  executes by exiting flowchart  400 . The records compiled or accessed in steps  402  through  408  may be updated accordingly. The disclosed embodiments track the modifications or customizations made to the existing prescription and update it into server  216  for pharmacy  206  to make the relative change into the medication packs. 
     The disclosed embodiments result in a more accurate and specific packaging for the patient, as shown in  FIG. 5 .  FIG. 5  depicts an improved packaging configuration of patient-customized medications according to the disclosed embodiments. The number of packs may be reduced using the above methods and processes. Here, packs  502  and  504  are shown, which hold the medication dosages shown in  FIG. 1 , but in a reduced number of packs. This helps prevent waste and improves convenience for the patient. 
     The medications are dispensed by day slots  508  and time slots  506  created in the packs according to the information provided by patient  202 . The time slots  506  are created horizontally to enable patient  202  to take his or her medication based on the preferred schedule. Of course the columns and rows may be swapped so that the columns represent days and the rows represent times. The time of each time slot is printed at the head (end) of the respective column (row) by printing station  318 , which also prints the patient&#39;s name and any special instructions. Indeed the entire top face of each pack, as illustrated in  FIG. 5 , with rows and columns to correspond to underlying bubbles or compartments may be printed by printing station  318 , together with days and times and different graphic representations of different medications (and/or other information specific to the underlying contents), each in a respective row/column intersection. The precise packaging methods disclosed above reduce the excess waste of packs and provide better compliance and efficacy with fewer side effects for patient  202 . 
     Custom time slot  510  represents the preferred slot selected by patient  202  according to the methods and processes disclosed above. Using device  204 , patient  202  puts a time into a graphic representation of a slot, and then drags and drops a graphic representation of the appropriate medicine for that slot. Additional custom time slots may be introduced by simply adding them to the end of the horizontal column (subject to the constraint that there are sufficient columns in the bubble pack or compartments in the packaging). 
     Further, the disclosed embodiments can auto track prescription updated done by providers and alerts patient  202  and physician  210 . This innovative approach allows immediate updates of prescription changes into its next medication packs. Patient  202  may receive a change of medication report along with instructions on how to remove a medication. This information also may be provided to a nurse or caregiver, which may be more applicable to an assisted living or other residential setting having medical staff on-call or available. 
     The disclosed embodiments, therefore, provides the following advantages over the conventional art. A patient can decide to take the medicine at a preferred time. Referring to  FIG. 5 , patient  202  may space out the dosages as they please. For example, the 7:30 am dose may be taken before breakfast while the 8:30 am dose ensures that it is taken on a full stomach. Another patient may configure the pack to show the first dosage as a 9 am dose before breakfast, and a 10 am dose on the full stomach. In the conventional method, it is not possible for a patient to modify the doses per his or her convenience or preference. 
     The disclosed embodiments also may include a combination of routine medications and non-routine medications. The routine medications may be placed in one slot, or bubble, with the non-routine medications placed in another slot, or bubble. This configuration may prevent confusion or a mishap by patient  202  by taking the wrong medication, especially if they do not need to take a non-routine medication. For example, patient  202  is getting 10 pills per pack, of which 7 are going to be routine (i.e., daily doses) for a long period of time and 3 are non-routine (i.e., take when needed). The disclosed embodiments may place the 7 routine pills in one bubble and other 3 in a single bubble. In other words, there may be different slots for these medicines such that the bubbles do not exactly match what is shown in  FIG. 5 . Three separate bubbles may be used in the event there are three different types of drugs. 
       FIG. 6  depicts an example of a label  600  for use in a medication dosage dispensing system according to the disclosed embodiments. The labels have been customized or modified and printed out for use on the medicine pack or onto vials. Label  600  is an example only, and the disclosed embodiments may include other variations. Label  600  may provide a visual guide to various medicines within the pack as well as dosage information. Thus, patient  202  may be able to easily track the types of medicine and the dosage times/days. 
     The approach presented by the disclosed embodiments allows the patient to modify the doses that can be sent to the doctor or pharmacy to approve the changes for the next medication pack. The patient would need to adhere to the doctor&#39;s prescription, and this feature is ensured by requiring approval, as disclosed above. 
     A patient may place his or her request for their medication packs from any location having a wireless or wired connection to a network. The patient uploads the request for customization or modification centrally to any pharmacy regardless of ownership. This feature allows the patient to obtain the medication in a preferred dosing and packaging configuration from any location. The patient is not limited to receiving the preferred dosage within the medicine packs for a “regular” pharmacy, but from any pharmacy. This is especially convenient for a patient that travels frequently, or resides in multiple places. 
     As shown by the configuration depicted in  FIG. 5 , the disclosed embodiments reduce the amount of packaging materials utilized in making the medicine packs. The packs are made according to a customized configuration so the redundancy is eliminated. There will not be four packs with an “A.M.” slot on them. 
     A novel process of customizing or modifying the daily doses of medications is disclosed. This process includes sending a request for approval from the patient to the doctor or pharmacy to modify the dosing schedule of at least one medication for a particular time schedule to be included in the next medication pack. The process also includes uploading, if necessary, the request for approval by the doctor or the pharmacy for the customization or modification of the at least one medication. Approval for the configured packaging of the customized or modified medication by the doctor or the pharmacy is communicated with a message to the patient. The process also includes dispensing of the medication manually or by a robotic automated dispensing system based on the dosing selection by the patient or a medical professional. 
     The request from the patient to the doctor or the pharmacy may be made via suitable communication modes, such as the Internet, smartphone, tablet, phone, and the like. 
     The auto dispensing of the medication is completed time-based manually or by a robotic automated system by creating slots on each pack according to day followed by a time schedule for each day as configured by the patient. This configuration may be reflected in the next medication pack generated. The slots are created by day, and each day is further time-classified for medication dispensed either manually or by the robotic automated system. 
     The disclosed embodiments also include a process of customizing or modifying the daily doses of medications. The patient has access to a database or server of the pharmacy, prescriber, or central prescription service. The patient also may have access to an insurance company&#39;s system. The patient may use this access to view and modify the dosage or timing of the medication. 
     The disclosed embodiments also include a process of customizing or modifying the daily doses of medications that allows the storing of default preferences for dosing. The default preferences take into account factors impacting medication efficacy, such drug interactions, time of day, food intake for best efficiency, and the like. It should be appreciated that the disclosed embodiments could be offered as a business method on a subscription or fee basis. For example, system  10  including transaction process  28  could be created, maintained or deployed by a service provider that offers the functions described herein for customers. A service provider could offer to deploy or provide the ability to process a logo and other content to generate a website using the disclosed processes. 
     In addition to being implemented as system and processes, the disclosed embodiments may be provided as a program product stored on a computer-readable medium, which, when executed, enables system  200  and robot packing system  208  to generate the medicine packs. To this extent, the computer-readable medium may include program code, which implements the processes and system disclosed herein. The term “computer-readable medium” includes one or more of any type of physical embodiment of the program code implementing the steps to execute the disclosed processes. In particular, the computer-readable medium can comprise program code embodied on one or more portable storage articles of manufacture, such as a compact disk, a DVD, a Blu-ray disk, a magnetic disk, a tape and the like, on one or more data storage portions of a computing device, such as a memory. 
     As used herein, the terms “program code” and “computer program code” are synonymous and refer to any expression, in any language, code or notation, of a set of instructions that cause a computing device having an information processing capability to perform a particular function either directly or after any combination of the following: (a) conversion to another language, code or notation; (b) reproduction in a different material form; or (c) decompression. To this extent, program code can be embodied as one or more types of program products, such as an application/software program, component software/library of functions, an operating system, a basic input/output system/driver for a particular computing or input/output device and the like. Terms such as “component” and “system” are synonymous as used herein and represent any combination of hardware or software capable of performing some function(s). 
     The block diagrams in the Figures illustrate the architecture, functionality and operation of possible implementations of system  200  and flowchart  400 , plus possible computer program products. Each block in the block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). The functions noted in the blocks may occur out of order noted in the figures. For example, two blocks shown in succession may be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. Each block of the block diagrams can be implemented by special purpose hardware-based systems that perform the specified functions or acts, or combinations of special purpose hardware and computer instructions. 
     It will be apparent to those skilled in the art that various modifications and variations may be made in the disclosed embodiments of the disclosed methods and systems without departing from the spirit or scope of the invention. Thus, it is intended that the present invention covers the modifications and variations of the embodiments disclosed above provided that the modifications and variations come within the scope of any claims and their equivalents.